Method of and apparatus for heat determination.



G. H. GIBSO I. METHOD 0F AND APPARATUS FOR HEAT DETERMINATION.

APPLICATION FILED DEC. I, 1916.

Patented May 28,1918.

d3:13 SHEETS-SHEET I.

jfl

e l e 3 G. H. GIBSON. METHOD 0F AND APPARATUS F03 HEATDETERMINATION.

APPLICATION FILED DEC. II 1916. 1,267,757, Patented May 28,1918.

3 SHEETS-SHEET 2.

G. H. GIBSON.

METHOD OF AND APPARATUS FOR HEAT DETERMINATION.

APPLlcATIoN FILED DEc.1.191e.

1,267,757. Patented May 28,1918.

3 SHEETS-SHEET 3.

RZ A2 ttozum GEORGE H. GIBSON, OF MONTCLAIR, NEW JERSEY.

METHOD 0F AND APPARATUS FOR HEAT DETERMINATION.

Specification of Letters Patent.

Patented May 28, 1918.

Application filed December 1, 1916. Serial No. 134,287.

To ali whom? t may concern Be it known that I, GEORGE H. GIBsoN,

a citizen of the United States of America, and a resident of Montclair, county of Essex, State of' New Jersey, have invented certain new and useful Improvements in Methods of and Apparatus for Heat Determination, of' which the following is a true and exact description, reference being had to the accompanying drawings, which form a part thereof.

The primary object of my invention is to provide simple and effective methods of and apparatus for determining the amount of heat lost or absorbed by a fluid in flowing between two separated points in a conduit through which the fluid passes. In carrying' out my invention, I create an electrical current modifying effect, which is proportional to the temperature difference between the separated conduit points and create a second electrical current modifying effect proporltional to the quantity rate of fluid flow in the conduit and utilize these current modifying effects in combination to obtain an indication proportional to the product of said effect. The product thus obtained is proportional to the product of the amount of fluid flow through the conduit multiplied by the difference in temperature of the fluid at the separated points of the conduit, and is therefore proportional to the amount of heat lost or absorbed by the fluid in flowing be! tween said points.

To create the electrical current modifying effect. proportional to the difference between the temperature of the fluid between the separated points of the conduit, I passau electrical current through resistance bodies which are subjected, one to the temperature of' the fluid at one point and another to the temperature at the second of the conduit points between which the change in heat is te be determined, which vary in resistance as their temperatures change by increments in exact or approximate linear proportion to the change in temperature. The resistance bodies 'subjected to the different temperatures are suitably connected into an electric circuit or circuits, to create a'current modifying effect therein proportional to the difference between the temperatures to which the bodies are subjected.

To obtain the sccond electrical current modifying eiicf. I employ a flow meter rcsponsive to the quantity rate of fluid flo-w through the conduit and utilize this flow meter to actuate a suitable electrical current regulator, as required to obtain the desired current modifying effect.

The two electrical current modifying efects obtained in the manner just described may be utilized in combination to give an indication of the desired product in various ways. In one simple and effective form of carrying out my invention, I obtain the desired result by employing the flow meter and the current regulator actuated thereby to cause an electrica-l current proportional in strength to the quantity rate of Huid flow through the conduit to pass through the resistance'bodies subjected to the temperatures at the separated points in the conduit. In

this case, a comparison-of the losses of potential in said resistance bodies gives the desired product, for the difference between the potential loss in one of the said resistances and the potential loss in the other of said resistance bodies will obviously be proportional to the product of the quantity rate of fluid flow through the conduit multiplied by the difference between the temperatures of the fluid at the two points at which the resistance bodies are located. The integrated di'erence between the losses in potential in the given resistances for a given period of time thus affords a direct measure for the amount of heat lost or absorbed by fluid passing between the two points of said conduit during said period of time.

In a second general mode of carrying out my invention, I utilize the resistance bodies to impress on an auxiliary resistance an electromotive force which is proportional to the difference in the temperatures to which the said resistance bodies are subjected. The auxiliary resistance on which the said electromotive force is impressed may be constant in amount, in which case I employ the flow meter to connect a portion of the said auxiliary resistance varying directly with the fluid rate of fiow into a galvanometer circuit. Instead of impressing the said electromotive force on a constant auxiliary resistance, I may employ the flow meter to maintain said auxiliary resistance on which said electromotive force is impressedinversely proportional in amount to the fluid rate of flow through the conduit.V

In other modes of carrying out my inveniro tion7 l employ resistance loodies to inaintain in one electric circuit an electrical current iiow proportional to the temperature change of the tluid, and employ the iiow ineter and current regulator actuated thereby to maintain a current low in another circuit whichv varies in proportion to the quantity rate of iiuid iiow, and inductively incasure the product oi2 the currents tion/ing in two said circuits, hy causing'd one current to ilow through the iield windings and the other through the armature conductors ot an electrical motor meter which may he of the integrating watt nieter type or may he an indicating or recording watt nieter in which the torque of the rnovalole ineter elei ent is resisted hy a spring or other loading device..

The invention niay he advantageously used for many purposes. For example7 it is well adapted for detern'iininp,1 the arnount oi heat furnished a user supplied with heat from acentrai station heating plant in which the circulating inediuni is hot water, and for measuring the reirigerating eiiect of a cooling fluid.

lhe various features of novelty which characterize my invention are pointed out with particularity in the claiins annexed to and. forming a part of this specication. F or a better understanding of the inventions however, and the advantages possessed hy it.: reference should he had to the accompanying drawings and descriptive :matter in which l have illustrated and c escrihed preferred forms oi apparatus and methods embodying iny invention.

@i the drawings:

Figure l is a diagrammatic representation of one forni oi apparatus adapted or use in determining the heat loss or alosorption oi a '.tluid flowing through conduit;

Fig. 2 is a partial sectional elevation talren on the line 2-2 et' Fig. l;

Fig. 3 is a diagrammatic representation ol a portion or a modiiied torni ci apparatus;

Fig. l is a view similar in character to Fig. 3, illustrating a dinerent nicdicationr,

ig. 5 is also a view siniilar to and illustrating still another rnodined torni or apparatus;

Fig. is a diagrammatic representation olE a forni or apparatus ot different type from those shown hy the preceding figures;

Fig. 7 is a diagrammaticrepresentation ci an apparatus generally siinilar to that shown in Fig. 6., hut einployinga simpliiication inade possible where a source oi constant electro-motive force is available;

llig. 8 is a diagrammatic representation illustrating a slight modification orn the apparatus shown in 7 Se is a diagrammatic r p;esentation of a forni oi e' at :atus in which electrithe apparatus shown in Figs. l and 2, EL.

represents a conduit through which a iiuid iiows, and l and ff represent points in said conduit at the opposite sides oi portion is thereof in which the iluid loses or absorbs heat, the quantity oi which it is desirable to determine. lor example, the portion es ci the conduit A may correspond to the heat radiating coils and house pipingl a user supplied with heat Jrrone. a central station by means of a circulating medium in the i'orrn oi hot water flowing through the conduit A.

The apparatus shown in liig. l comprises ineens for automatically maintaining an electric current now of a strength proportional to the quantity rate ci flow through the conduit fl. rlhe ineans employed for this purpose comprise a di'erential pressure device having its high and low pressure chainloers B and B2 respectively connected Aley pipes o and Z22 respectively to points in the conduit A between which a diderence of pressure exists which is a function or" the lvelocity head and hence of the rate of flow through the conduit. F or example, as shown, the pipes o and o2 are connected to the conduit el at the high and low pressure sides respectively, of a restricted orice A4 provided in the conduit., The derential pressure device i3 in the construction shown,

-has its chaniloers B and B2 separated by a iienilole diaphragm C. v The diaphragm is connected at its center to a stern B3 which is also connected to flexible diaphragme C and C2. The latter are equal to one another size out are smaller than the diaphragm C.. The diaphragme C and C2 close apen tures in the walls oiE the chambers l and B2 reinote from the diaphragm C, and make stuling box provisions :tor the stein unl necessary.

rl`he stern B3 is pivotally connected at its upper end to a lever l), to the opposite end of which is secured the movable coil c ci the electro-magnetic balancing device l. els shown, the lever D is formed hy two inetal hars D and D2 insulated troni each other5 and forming the terminals oi the coil e. The lever is suspended :troni a-ed support d hy derrihle conductors alA and Z2 connected at their lower ends to the'bars l and D2 respectively. The knife-edge pivot la carriedhy the lever D and the stein B3 engaging the pivot D3 are insulated from the hars D and D2. The electro-magnetic balancing device E also comprises stationary r ofia neutral position.

coils e and e2 coaxial with and located one above and the other below the coil e. When an electric current is caused to iiow in series through the coils e, c and c2 by the circuit connections hereinafter referred to, the coil e is attracted by the coil e2 and repelled by the coil e.

The means shown for adjusting the electric current ow through the coils e e and e2 to impress the required variable balancing force on the lever D, comprises a rheostat G, a reversible electric motor H, and controlling provisions for operating the latter in one direction or the other in response to the movements of the lever D out The rheostat G, as somewhatconventionally illustrated, comprises a contact member G movable along and engaging one or another of the stationary contacts G2 connected at intervals to a resistance conductor G3. As shown, the member G has a theaded passage receiving the threaded shaft H of the motor H. The motor H in the arrangement illustrated runs in one direction when a suitable source Y of electric current is connected to its terminals-H2 and H3, and in the opposite direction when current is supplied to the motor terminals H2 and H4.

K represents an electric battery or other suitable source of electric current`for the balancing device K` and for the motor H. One terminal of the battery K is connected by the conductor Z to the flexible support d for the lever D and thereby to the bar D which forms one terminal of the foating coil e. The bar D2 forming the other terminal o f the coil e is connected through the iiexible conductor d2 and the conductor 2 to one terminal of the stationary coil e. The second terminal of the stationary coil e is connected by a conductor 3 to one `terminal of the coill e2. The second terminal of the coil e2 is connected as shown, by a conductor 4f to one terminal of the ammeter l. The second terminal of the ammeter l is connected by the flexible conductor 5 to the movable element G of the rheostat G. rl`he resistance conductor G8 of the rheostat G is connected at one end to the' second terminal of the source of current K by conductors 6 and 6B, and the multiple circuit connections between these conductors.

, These multiple circuit connections compriseva resistance R located in the conduit A at the point A', and having one terminal connected directly to the conductor 6 and its other terminal connected by' the conductor 6A to one terminal of a resistance R2 located in the conduit A at the point A2 and having its second terminal connected` directly to the conductor 6B. Also located in the conduit A at the point A is a resistance 9^ haring one terminal connected by the c ondnctor to the conductor 6B, and having its second terminal connected by the conductor 6D to one terminal of a second resistance r2 located in the conduit A at the point A2. The second terminal of the conductor r2 is connected by a conductor 6E to the conductor 6. Between the conductors 6A and 6D is connected an instrument Q for measuring the difference in potential between the conductors 6A and 6D. This instrument Q may be a galvanometer, a potentiometer, 0r some other suitable type of sensitive volt meter, and in the practical use of my invention will ordinarily be a recording or integrating instrument.

Preferably the resistance bodies R', R2, 1" and r2 are of equal resistance when at the same temperatures and each should be- Aformed of a metal, or combination of metals such that a change in temperature of the Ibodywill result in a change in its electrical resistance which'is approximately in linear proportion to the change in temperature through the range in temperature to which the body is subJected in carrying out the invention. For example, in using the invention as illustrated to measure the heat lost in a hot water heating system, the resistance bodies may be formed of pure copper.

In operation, the differential of the pressures in the chambers B and B2 will be proportional to the square of the Huid rate of flow'through the orifice A4, and this pressure diiierential acting on one end of the lever D is balanced by the electro-magnetic interaction between the movable coil e carried by the opposite end of the lever D and the stationary coils e and e2. This electromagnetic interaction exerts aforce on the lever D which is proportional to the square of the current flowing in series through the coils c, e and e2. As the pressure difierential to which the diaphragm C is subjected increases, this moves the lever D into engagement with the contact L and causes the motor H to rotate in a direction to reduce the amount of the resistance conductor G3 interposed between the conductors 6B and 5, and thus restore the balance. Similarly.i on a diminution of the dierential pressure on the diaphragm C, the lever D engages the contact LA and thereby causes the motor H to increase the amount of the resistance conductor G3 interposed between the conductors 5 and 6B.

The apparatus shown in Fig. l operates automatically to maintain an electric current fiow through the coils e, e and e2 which is in linear proportion to the quantity of fluid fiowing through the restricted oriice A4. A

Since the resistance bodies R', R2, r and r2 all have the samefresistance at the same temperature, and eachivaries in resistance in direct proportion to the variation in temperature to which it is subjected, one half of Laenge? arm T movable over andin electric contact with the resistance r3, a worm wheel T carrying the arm T and rotated in one direction or the other, as hereinafter explained, by means of a reversible motor HA, which may be similar in construction to the motor H previously described, and has its threaded spindle in mesh with the worm wheel T. The motor HA has its common terminal H2 connected to the conductor 6 and has its terminals H3 and H4 connected to switch contacts S3h on opposite sides of a switch arm S which 'is connected to the conductor 6B and is,r carried by the oscillating element of a galvanometer S. The latter comprises an arc-shaped polarized armature S2 surrounded by a coil S3. The coil S3 has one terminal connected to the switch arm T. The second terminal of the coil S is suitably connected to a contact member M3, which'is carried by an oscillating ow meter M, and is adapted to sweep over a resistance R3 which is connected at one end to the conductor 6D and at the other end to the conductor 6A so that the current flow through the resistance R3 varies (with any given value of the electromotive force of the source K) in proportion with the temperature diilereuce between the points A and A2 of the conduit A. The How meter M shown in Fig. G, is ot a known type, comprising a U-tube M3 mounted in a carrier M, which is pivoted on the knifeedge fulcrum h 3. The U-tube is partially filled with mercury. One leg Mt of the U- tube ll/ 3 has its upper end connected by ilexible conduit m to the conduit A, so as to transmit the static pressure in the latter to the upper end of the column of mercury in leg M4. Similarly, a flexible conduit m transmits the velocity pressure in the conduit A adjacent to the point to which the eXible conduit m is connected to the upper end of the second` leg M5 of the U-tube.

With this type of meter, the Huid tlow through the conduit A creates a diierence in the pressure transmitted through the conduit m and .m to the legs of the U-tube, which is proportional to the square ofthe fluid rate of tlow through the conduit. The dierence in the pressures thus impressed on the upper ends of the columns of mercury in the legs of the U-tube produces a corresponding displacement of the mercury, thus shifting the center of gravity of the U-tube and turning the latter about its fulcrum point in a clockwise direction. The resistance R3 is so arranged relative to the ow meter that in the no-iiow condition through the conduit, the meter-carried Contact M3 will be at the terminal of the resistance R3 connected to the conductor 6D and, at the maximum iow through the conduit A for which the apparatus is designed, the contact M3 will engage the terminal of the resistance R3 connected to the conductor 6A. At intermediate flows,

the contact M3 occupies such positions that portions of the resistance R3 above the contact M3 will bear the same ratio to the total resistance R3 which said intermediate rate of flow bears to the maximum rate of How for which the apparatus is designed. This result is obtained with the apparatus shown by a uniform distribution of the resistance R3 along its length combined with a special shaping of the two legs of the U-tube, required to make the turning movements of the meter M directly proportional to the changes in the rate of flow through the conduit A which produce such turning movements. The mathematical formulae governing the shaping of the U-tube legs to obtain this result are well known to those skilled in the art and need not be stated herein, as they form no part of the present invention.

A current flow through the coil S3 moves the polarized armature S2 in one direction or the other, according to direction of current flow through the coil S3. The consequent movement of the switch arm S into engagement with the one. or the other 'of the switch contacts S4 energizes the motor HA for operation in whichever of the two directions it should run to move the switch arm T into the position in which there is no current flow through the coil S3. The position of the switch arm T in which there is no current flow through the coil S3 is necessarily that in which the switch arm T and contact M3 are at the same potential. Since the resistances 1'3 and R3 are connected together at the point lO, the contacts M3 and switch arm T are at the saine potential when the voltage drop through the portion of the resistance R3 above the contact M3 is equal to the voltage drop through the portion of the slide wire resistance to the left of the switch arm T.

lVith no current flow through the coil S3 of the galvanometer S the switclrarm S occupies the neutral position shown in Fig. 6. lilith a current ilow through the coil S3 in one direction the switch arm S will move upward from the neutral position, and with a current iiow through the coil S3 in the opposite direction the switch arm S will move downward from the neutral position. The galvanometer S thus forms an electrical indicating device connected between the contacts M3 and T.

l/Vith the apparatus shown in Fig. 6, the amount of resistance of the portion of the slide wire resistance r3 between the switch arm T and the point l() when there is no current flow through the coil S3, is proportional to the product of the quantity rate of flow through the conduit A multiplied by the difference in temperatures between the points A and A3.

To understand this, assume that C equals sul the equal electric currents flowing at any instant through the conductors 6A and 6D and that, at the saine instant, l? represents the rate of iluid ilow through the conduit A and t the diiierence in temperatures between the points A and i2 and that, at the saine instant, i150 is the ohmic measure or" the resistance i" to the lett ot the switch arm T. Assume, also, that li" is a constant equal to the rate oi flow through the conduiti which will causenthe contact h 6 to engage Ythe lower terminal of the resistance R and that a, and l), are other suitable constants, llith these assumptions, the dilierence in potentialbetween the opposite ends of the resistance Tl will be equal to wilt, and the diterence in potential between the upper of the resistance l and the contact ld@ will be equal to is thus equal to Cim, it follows that llt is equal to FWS or, in other words, the product ot the rate of tion' through conduit it multiplied by the change in temperature between the points Y and A2 is proportional to the ohmic resistance of the portion of the resistance 715 to the lett et the switch arm T. Tt follows, therefore, that the numerical value ot the desired product may be determined by means or" scale marks T2 along which the end of the switch arm T sweeps.

The apparatus shown in Fig. 7 differs troni that shown in YFig. 6 in the omission ot the resistances R5 and r" and in the omission et the galvunometer S, potentiometer T and motor lin. ln Fig. 7, a galvanometer lili.' has one of its terminals connected to the terminal of the resistance l" away from which the switch Contact M is moved by the flow meter M, as the flow through the conduit A, increases, and thesecond terminal oit the galvanometer lh is connected to the switch contact lil. With this arranfremeut *P the current flow through the windings ci the galvanometer lA will be proportional to the product of the quantity rate ot fluid flow through the conduit A multiplied by the difference in temperature orp the tiuid at the points A and A2 in the conduit, provided the source l of current K impresses a constant electromotive torce on the conductors 6 and 6D. The apparatus shown in Fig. 7 while obviously simpler than that shown in 6, is less practical, because of the necessity for maintaining a Constant potential diii'erence between the supply conductors 6 Y terminal ci the resistance i 6 is not connected to the conductor 6B, while the switch con1 tact M carried by the flow meter M is oon= nected through'the windings or the galran ncnieter la to the conductor 6l). il] ith this form ci' apparatus, it will be apparent that the portion ot the resistance its below the Contact M is the only portion of the resistance ll in circuit, and the current iiow through the galyanometer TA will be directly proportional to the product of the quantity of tluid tiow through the conduit multiplied by the difference iu temperature oi' the conduit points it and A2, it the source of current l is a source of constant electromotive force.

ln the modilied torni of apparatus shown in Fig. i) the resistances R and R2, r and i"' are connec` ed to the source ot current l', as in lfig. l.` The resistance Re over which the llow meter oi switch contact M6 sweeps,

as in Fig. 6, has its terminals connected to the terminals of the current source l. ln this form of apparatus, a motor meter U of the integrating watt meter type is employed. The armature windingsV U2 of the motor meter have their terminals connected to the bars ci the commutator U5. @ne of the cominutator brushes is connected to the iiow meter contact lil, and the other brush is connected to the conductor 6B. l/l/vhile the armature windings of the meter are thus connected in a shunt about the portion oit the resistance ll above the Contact M6, the resistance ot this shunt should and naturally would be so great relative to the ohmic value ot the resistance Re that the current ilow through the shunt will not appreciably alter.

the potential drop in the portions of the resistance Re above and below the contact M6., The lield windings U6 of the meter are connected in series between the conductors 6A and 6l). The conducting drag disk U3 of the meter is inductively acted upon by a coil li'7 which has its terminals connected, one to iho conductor 6 and the other to the conductor 6B. TWith this arrangement, the current tlowing' through the iield windings U65 of the motor meter will vary with the temperature difference between the points A and ft2 of the conduit A, and the current through the armature of the motor mete will be proportional to the quantity rate oi.y

iluid flow through the conduit. The meter 'U serves to inductively multiply the two currents passing through its armature and field windings, and the counting wheels llt of the meter will thus give the integrated value of the heat lost or absorbed by the iiuid tlow through the conduit between the points A nanars? and A The drag coil U7 renders the meter indications independent of fluctuations in the voltage of the current supply source K. Where the current supply source K is replaced by a source KA of constant electromotive force, the drag coil U7 may be replaced by the usual permanent magnet Us as shown in Fig. l0.v

YWhile in accordance with the provisions of the statutes, I have illustrated and described the best forms of apparatus and methods now known to me for accomplishing the object of my invention, it will be apparent to those skilled in the art that my invention may be embodied in apparatus and carried out by methods specifically different from those disclosed herein.

Having now described my invention, what l claim as new and desire to secure by Letters Patent, is

l. The method of determining the amount of' heat lost or absorbed by fluid in flowing between separated points in a conduit, which consists in creating an electrical current modifying effect proportional to the temperature difference between said points, and in creating an electrical current modifying effect proportional to thequantity rate of fluid flow in said conduit, and utilizing said current.. modifying e'ectsl in combination to thereby obtain an indication proportional to the product of said effects.

rlhe method of determining the amount of' heat lost or absorbed by fluid in flowing between separated points in a conduit, which consists in creating an electrical current modifying effect proportional to the temperature difference between said points by means of electrical resistances subjected to the temperatures of the fluid at said points and varying in resistance with the temperavtures to which they are subjected, and in creating an electrical current modifying effect proportional to the quantity rate of fluid flow in said conduit by means of a device responsive to said rate of flow and a current regulator actuated thereby and influencing an electrical indicating means jointly by the current modifying eiects produced to thereby obtain an indication proportional to the product of said effects.

3. The combination with a conduit, of means for determining the amount of heat lost or absorbed by fluid in flowing between separated points in said conduit, comprising resistances subjected to the temperatures of the fluid at said points and varying ln resistance with the temperatures to which they are subjected according tol a pre-determined law, a flow meter responsive to the quantity rate of fluid flow through said conduit, a current regulator actuated by said device, and-electrical indicating means operatively connected to said resistances and to said current regulator and jointly ini 4. The combination with a conduit, of

means for determining the amount of heat lost or absorbed by fluid in flowing between separated points in said conduit, comprising means including parts subjected to the ten'iperatures at said points and adapted to exert an electric current modifying effect proportional to the difference in temperature at said points, means responsive to the fluid rate of flow through said conduit, a current regulator actuated thereby and electrical exhibiting means operatively connected to the first mentioned means and to said current regulator and jointly influenced thereby to indicate the product of said rate of flow and the differences of temperaturev between said points.

5. Electrical resistance means for determining the difference in temperature at two points, comprising in combination a pair of similar resistances located at, each of said points and each varying in the amount of its resistance with the temperature to which A it is subjected, a source of current, circuit connections providing two parallel circuits supplied with current from said source and each including a resistance at each of said points, said connections being so arranged that the current Hows between the two resistances located at each point and the resist-ances in series therewith respectively and located at the other conduit point, are in opposite directions, and a cross connection between said parallel circuits connected to each of the latter between the two resistances therein.

G. The combination with a conduit of means for determining the amount of heat lost or absorbed by fluid in flowing between separated points in said conduit, said means comprising a source of eleetro-niotivel force, parallel circuits connected to said source and including resistances subjected to the temperatures of the fluid at said points and varying in resistance with the temperatures to which they are subjected according to a predetermined law, an external resistance connected to said parallel circuits at points therein between which exists a potential difference due to the difference in the temperatures of said conduit points, a measuring instrument, means for including in circuitJ said measuring instrument a portion of said outside resistance varying proportionately with the quantity rate ot fluid flow through said conduit.

7. rlhe combination with a conduit, of means for determining the amount of heat lost or absorbed by fluid in flowing between separated points in said conduit, said means fio comprising a source ciE electro-motive torce, parallel circuits connected to said source and including resistances subjected to the temperatures of the tluid at said points and varying in resistance with the temperatures to which they are subjected according to a predetermined law, an external resistance connected to said parallel circuits at points therein between which a potential difierence erists dueto the diilerence between the temperatures at said conduit points, an electrical indicating device, a flow meter rcsponsive to the quantity rate or tluid flow through said conduit, and a contact actuated by said meter to include a portion or said external resistance in circuit with said indicating device varying proportionateljT with the quantity rate ot iluid idow through said conduit.

8. Means for determining the amount et hea-t lost or absorbed by a` iluid in tlowing between two sepa-rated points. in a conduit, comprising in combination a source ci current, circuit connections providing two parallel circuits supplied with current Afrom said source and each including a resistance at eacloof said points and an intermediate connecting portion, said connections being so arranged that the currents flow in oppo site directions through said circuits between the resistances located at said separated points, a cross connection between the intermediate portions ot said parallel circuits, a pair ot movable contacts, one movable along said cross connection and the other along one oi said intermediate circuit portions, and electrical indicating. means connected between said contacts.

9., Means for determining the amount ot heat lost or absorbed by a duid in dowing between two separated points in a conduit, comprising in combination a source or" current, circuit connections providing two parallel circuits supplied with current trom.

' neet/,7er

said source and each including a resistance said intermediate circuit portions, electrica-l ,i

indicating means connected between said contacts, and a flow meter responsive to the quantity rate et fluid 'dow throng'h said con-1 duit and moving the iirst-inentioned contact along said cross `connection in proportion to said rate or tlowu itl. Means -tor determining the amount ci heat lost or absorbed by a iluid in dowing between two separated points in a conduit, com )rising in combination a source ot eurrent, circuit connections providing two parallel circuits supplied with current from said source and each including a resistance at each of said points and an intermediate connecting portion, said connections being so arranged that the currents i'iow in opposite directions through said circuits between the resistances located at said separated points, a cross connection between the intermediate portions of said parallel circuits, a contact movablealong said cross connec= tion, a second contact movable along one of said intermediate cir-cuit portions, a dow I meter responsive to the quantity rate of fluid ilow through said conduit and moving the viirst-mentionsd contact along said cross connection in proportion to said rate ot dow and means responsive to the potential dierence between said contacts for adjusting said second contact to minimize said potential diterence encuen unison. 

